Systems and Methods for Structurally Interrelating Components Using Inserts Made from Metallic Glass-Based Materials

ABSTRACT

Systems and methods in accordance with embodiments of the invention operate to structurally interrelate two components using inserts made from metallic glass-based materials. In one embodiment, a method of structurally interrelating two components includes: forming an insert from a metallic glass-based composition; where the formed insert includes a metallic glass-based material; affixing the insert to a first component; and structurally interrelating the second component to the first component using the insert.

CROSS-REFERENCE TO RELATED APPLICATIONS

The current application is a continuation of U.S. application Ser. No. 15/067,561, filed Mar. 11, 2016, which application claims priority to U.S. Provisional Application No. 62/131,467, filed Mar. 11, 2015, the disclosures of which are incorporated herein by reference in their entireties.

STATEMENT OF FEDERAL FUNDING

The invention described herein was made in the performance of work under a NASA contract NNN12AA01C, and is subject to the provisions of Public Law 96-517 (35 USC 202) in which the Contractor has elected to retain title.

FIELD OF THE INVENTION

The present invention generally relates to structurally interrelating components using inserts fabricated from metallic glass-based materials.

BACKGROUND

The manufacture of a variety of engineered structures typically relies on fastening, or otherwise structurally interrelating, a plurality of components (e.g. in the form of sheet metal). In many instances, conventionally engineered structures are assembled from components made from heritage engineering materials, e.g. steel, aluminum, titanium, etc. Such materials are advantageous in a number of respects, e.g. they are characterized by the requisite toughness for a host of engineering applications. Moreover, such heritage engineering materials can be readily amenable to being adjoined to other engineering materials. For example, threaded holes (which can accommodate screws/bolts) can be practicably machined into steel-based components.

Many modern structures rely on the implementation of composite materials that may not be as easily machinable as heritage engineering materials. For example, carbon fiber composites typically cannot be easily threaded. Accordingly, in many instances, to allow carbon fiber composite materials to be adjoined to other components, threaded inserts are embedded within carbon fiber composite materials that can more easily enable them to be adjoined to other components. For instance, holes can be drilled out of a carbon composite material, and threaded inserts that define threaded holes—typically machined from heritage engineering materials (e.g. steel, aluminum, titanium)—can be epoxy bonded within the holes drilled in the carbon composite material. The embedded threaded inserts can thereby enable another component (e.g. sheet metal made from steel) to be fastened to the carbon fiber composite.

SUMMARY OF THE INVENTION

Systems and methods in accordance with embodiments of the invention operate to structurally interrelate two components using inserts made from metallic glass-based materials. In one embodiment, a method of structurally interrelating two components includes: forming an insert from a metallic glass-based composition; where the formed insert includes a metallic glass-based material; affixing the insert to a first component; and structurally interrelating the second component to the first component using the insert.

In another embodiment, forming an insert from a metallic glass-based composition includes using one of: a thermoplastic forming technique; and a casting technique.

In yet another embodiment, the formed insert includes a textured outer surface.

In still another embodiment, the formed insert is a threaded insert.

In still yet another embodiment, the formed insert includes extensions that are configured to deploy as the insert is engaged by a screw.

In a further embodiment, the formed insert includes an eye-hook structure.

In a yet further embodiment, the formed insert conforms to one of a cup-shaped geometry and a cone-shaped geometry.

In a still further embodiment, the metallic glass-based composition is based on one of: Ti, Zr, Cu, Ni, Fe, Pd, Pt, Ag, Au, Al, Hf, W, Ti—Zr—Be, Cu—Zr, Zr—Be, Ti—Cu, Zr—Cu—Ni—Al, Ti—Zr—Cu—Be, and combinations thereof.

In a still yet further embodiment, the metallic glass-based composition is based on titanium.

In another embodiment, affixing the formed insert to a first component includes epoxy bonding the formed insert to the first component.

In still another embodiment, affixing the formed insert to a first component includes press fitting the formed insert in to the first component.

In yet another embodiment, the formed insert is a threaded insert such that when it is engaged by a screw, it expands laterally and thereby better adheres to the first component.

In still yet another embodiment, the first component is a carbon composite material.

In a further embodiment, the metallic glass-based material is a titanium-based metallic glass-based material.

In a still further embodiment, the formed insert is a threaded insert, and structurally interrelating the second component to the first component includes fastening the second component to the first component using a screw and the threaded insert.

In a yet further embodiment, structurally interrelating the second component to the first component includes structurally aligning the second component to the first component.

In a still yet further embodiment, an insert configured to structurally interrelate two components includes a metallic glass-based material.

In another embodiment, the insert is a threaded insert.

In yet another embodiment, the insert includes an eye-hook structure.

In still another embodiment, the insert includes a titanium-based metallic glass-based material.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a bolt cast from a MG-based material, demonstrating that MG-based materials can be cast into shapes that include intricate features such as threads in accordance with certain embodiments of the invention.

FIG. 2 illustrates a process for structurally interrelating two components using an insert fabricated from a MG-based material in accordance with certain embodiments of the invention.

FIGS. 3A-3C illustrate casting a MG-based material to create a threaded insert in accordance with certain embodiments of the invention.

FIGS. 4A-4I illustrate a variety of insert geometries that can be fabricated in accordance with certain embodiments of the invention.

FIGS. 5A-5C illustrate a threaded insert including extensions fabricated from a MG-based material in accordance with certain embodiments of the invention.

FIGS. 6A-6B illustrate how the elastic properties of a MG-based material can be harnessed to better adhere a respective insert to a component in accordance with certain embodiments of the invention.

FIGS. 7A-7D schematically depict a process for structurally interrelating two components using an insert fabricated from a MG-based material in accordance with certain embodiments of the invention.

FIGS. 8A-8B illustrate an insert that was fabricated from conventional steel relative to an insert fabricated from a MG-based material in accordance with certain embodiments of the invention.

DETAILED DESCRIPTION

Turning now to the drawings, systems and methods for structurally interrelating two components using inserts made from metallic glass-based materials are illustrated. In many embodiments, threaded inserts that include metallic glass-based materials are embedded within at least a first component to be adjoined to a second component; the threaded insert is then utilized in the adjoining of the at least two components. In a number of instances, cup and cone-shaped inserts that include metallic glass-based materials are embedded within first and second components, and the cup and cone-shaped inserts are used to structurally align the first and second components.

Metallic glasses, also known as amorphous alloys, embody a relatively new class of materials that is receiving much interest from the engineering and design communities. Metallic glasses are characterized by their disordered atomic-scale structure in spite of their metallic constituent elements—i.e. whereas conventional metallic materials typically possess a highly ordered atomic structure, metallic glass materials are characterized by their disordered atomic structure. Notably, metallic glasses typically possess a number of useful material properties that can allow them to be implemented as highly effective engineering materials. For example, metallic glasses are generally much harder than conventional metals, and are generally tougher than ceramic materials. They are also relatively corrosion resistant, and, unlike conventional glass, they can have good electrical conductivity. Importantly, metallic glass materials lend themselves to relatively easy processing in certain respects. For example, the forming of metallic glass materials can be compatible with injection molding processes. Thus, for example, metallic glass compositions can be cast into desired shapes.

Nonetheless, the practical implementation of metallic glasses presents certain challenges that limit their viability as engineering materials. In particular, metallic glasses are typically formed by raising a metallic alloy above its melting temperature, and rapidly cooling the melt to solidify it in a way such that its crystallization is avoided, thereby forming the metallic glass. The first metallic glasses required extraordinary cooling rates, e.g. on the order of 10⁶ K/s, and were thereby limited in the thickness with which they could be formed. Indeed, because of this limitation in thickness, metallic glasses were initially limited to applications that involved coatings. Since then, however, particular alloy compositions that are more resistant to crystallization have been developed, which can thereby form metallic glasses at much lower cooling rates, and can therefore be made to be much thicker (e.g. greater than 1 mm). These metallic glass compositions that can be made to be thicker are known as ‘bulk metallic glasses’ (“BMGs”). As can be appreciated, such BMGs can be better suited for investment molding operations.

In addition to the development of BMGs, ‘bulk metallic glass matrix composites’ (BMGMCs) have also been developed. BMGMCs are characterized in that they possess the amorphous structure of BMGs, but they also include crystalline phases of material within the matrix of amorphous structure. For example, the crystalline phases can exist in the form of dendrites. The crystalline phase inclusions can impart a host of favorable materials properties on the bulk material. For example, the crystalline phases can allow the material to have enhanced ductility, compared to where the material is entirely constituted of the amorphous structure. BMGs and BMGMCs can be referred to collectively as BMG-based materials. Similarly, metallic glasses, metallic glasses that include crystalline phase inclusions, BMGs, and BMGMCs can be referred to collectively as metallic glass-based materials or MG-based materials.

The potential of metallic glass-based materials continues to be explored, and developments continue to emerge. For example, in U.S. patent application Ser. No. 13/928,109, D. Hofmann et al. disclose the implementation of metallic glass-based materials in macroscale gears. The disclosure of U.S. patent application Ser. No. 13/928,109 is hereby incorporated by reference in its entirety, especially as it pertains to metallic glass-based materials, and their implementation in macroscale gears. Likewise, in U.S. patent application Ser. No. 13/942,932, D. Hofmann et al. disclose the implementation of metallic glass-based materials in macroscale compliant mechanisms. The disclosure of U.S. patent application Ser. No. 13/942,932 is hereby incorporated by reference in its entirety, especially as it pertains to metallic glass-based materials, and their implementation in macroscale compliant mechanisms. Moreover, in U.S. patent application Ser. No. 14/060,478, D. Hofmann et al. disclose techniques for depositing layers of metallic glass-based materials to form objects. The disclosure of U.S. patent application Ser. No. 14/060,478 is hereby incorporated by reference especially as it pertains to metallic glass-based materials, and techniques for depositing them to form objects. Furthermore, in U.S. patent application Ser. No. 14/163,936, D. Hofmann et al., disclose techniques for additively manufacturing objects so that they include metallic glass-based materials. The disclosure of U.S. patent application Ser. No. 14/163,936 is hereby incorporated by reference in its entirety, especially as it pertains to metallic glass-based materials, and additive manufacturing techniques for manufacturing objects so that they include metallic glass-based materials. Additionally, in U.S. patent application Ser. No. 14/177,608, D. Hofmann et al. disclose techniques for fabricating strain wave gears using metallic glass-based materials. The disclosure of U.S. patent application Ser. No. 14/177,608 is hereby incorporated by reference in its entirety, especially as it pertains to metallic glass-based materials, and their implementation in strain wave gears. Moreover, in U.S. patent application Ser. No. 14/178,098, D. Hofmann et al., disclose selectively developing equilibrium inclusions within an object constituted from a metallic glass-based material. The disclosure of U.S. patent application Ser. No. 14/178,098 is hereby incorporated by reference, especially as it pertains to metallic glass-based materials, and the tailored development of equilibrium inclusions within them. Furthermore, in U.S. patent application Ser. No. 14/252,585, D. Hofmann et al. disclose techniques for shaping sheet materials that include metallic glass-based materials. The disclosure of U.S. patent application Ser. No. 14/252,585 is hereby incorporated by reference in its entirety, especially as it pertains to metallic glass-based materials and techniques for shaping sheet materials that include metallic glass-based materials. Additionally, in U.S. patent application Ser. No. 14/259,608, D. Hofmann et al. disclose techniques for fabricating structures including metallic glass-based materials using ultrasonic welding. The disclosure of U.S. patent application Ser. No. 14/259,608 is hereby incorporated by reference in its entirety, especially as it pertains to metallic glass-based materials and techniques for fabricating structures including metallic glass-based materials using ultrasonic welding. Moreover, in U.S. patent application Ser. No. 14/491,618, D. Hofmann et al. disclose techniques for fabricating structures including metallic glass-based materials using low pressure casting. The disclosure of U.S. patent application Ser. No. 14/491,618 is hereby incorporated by reference in its entirety, especially as it pertains to metallic glass-based materials and techniques for fabricating structures including metallic glass-based materials using low pressure casting. Furthermore, in U.S. patent application Ser. No. 14/660,730, Hofmann et al. disclose metallic glass-based fiber metal laminates. The disclosure of U.S. patent application Ser. No. 14/660,730 is hereby incorporated by reference in its entirety, especially as it pertains to metallic glass-based fiber metal laminates. Additionally, in U.S. patent application Ser. No. 14/971,848, A. Kennett et al. disclose techniques for manufacturing gearbox housings made from metallic glass-based materials. The disclosure of U.S. patent application Ser. No. 14/971,848, is hereby incorporated by reference in its entirety, especially as it pertains to the manufacture of metallic glass-based gearbox housings.

Notwithstanding all of these developments, the vast potential of metallic glass-based materials has yet to be fully appreciated. For instance, the fabrication of inserts that can be used to facilitate the structural interrelationship between two components from metallic glass-based materials has yet to be fully explored. Such inserts have typically been fabricated from conventional engineering materials such as steel, aluminum, and/or titanium. This is in part due to the conventional desire to not have two dissimilar metals in intimate contact with each other—i.e. a screw and the respective threaded insert each including dissimilar metals—for fear of the effects of galvanic corrosion. However, MG-based materials can be made to be relatively averse to the effects of galvanic corrosion, and can also be made to develop a robust oxide layer that can further inhibit occurrences of galvanic corrosion. In other words, MG-based materials can be made to practicably operate in intimate contact with dissimilar metals. Whereas such inserts have typically been fabricated from conventional engineering materials (e.g. steel, aluminum, or titanium), they can substantially benefit from the materials properties that many MG-based materials can offer. For instance, inserts made from MG-based materials can have a relatively higher elastic strain limit, better resistance to wear, higher hardness, lower density, better corrosion resistance, and/or better resilience to extreme environments relative to conventionally fabricated inserts. Additionally, MG-based materials can be further advantageous insofar as their inherent mechanical properties can be tunable via alloying. Moreover, MG-based materials are amenable to casting and other thermoplastic forming processes, which can greatly enhance manufacturing efficiency. By contrast, casting processes are not conventionally used in the fabrication of inserts from heritage engineering materials for a number of reasons. For example, the most appropriate conventional materials for casting techniques are softer materials, which typically are not wear resistant and thereby not best-suited for, e.g., threaded insert applications where screws may be wearing on the respective insert. Methods for structurally interrelating two components using inserts that include MG-based materials in accordance with many embodiments of the invention are now discussed below.

Methods for Structurally Interrelating Two Components Using Inserts Fabricated From MG-Based Materials

In many embodiments of the invention, two components are structurally interrelated using inserts fabricated from MG-based materials. While conventional inserts fabricated from heritage engineering materials have been effective in many respects, fabricating these inserts from MG-based materials can offer a host of previously unrealized advantages. As alluded to above, MG-based materials can offer unique materials profiles that can be advantageous such inserts. Moreover, MG-based materials are amenable to casting and other thermoplastic forming processes, which can allow for the efficient—and—bulk manufacture of even intricate geometries. For example, FIG. 1 illustrates a screw—including threads—that was entirely cast from a MG-based material; FIG. 1 demonstrates that MG-based materials can be cast into intricate geometric shapes. This level of castability can be harnessed in the creating inserts from metallic glass-based materials.

FIG. 2 illustrates a process for structurally interrelating two components in accordance with certain embodiments of the invention. In particular, the method 200 includes forming 210 an insert from a MG-based composition using a casting technique or other thermoplastic forming technique. Any suitable thermoplastic or casting technique can be implemented in accordance with embodiments of the invention. For example, FIGS. 3A-3C schematically illustrate casting a MG-based material to create a threaded insert in accordance with many embodiments of the invention. In particular, FIG. 3A illustrates a MG-based composition in relation to a mold in the shape of a screw; FIG. 3B illustrates casting the MG-based melt around the mold so as to form a MG-based material; and FIG. 3C illustrates removing the cast threaded insert from the plug. In many instances, the forming 210 additionally includes other manufacturing procedures, such as machining. For instance, the forming 210 can include roughening the outer surface of the insert via any of a variety of texturizing techniques.

Note that any suitable MG-based material can be incorporated in accordance with embodiments of the invention; embodiments of the invention are not limited to particular compositions. For example, in many instances, the alloy composition is a composition that is based on one of: Ti, Zr, Cu, Ni, Fe, Pd, Pt, Ag, Au, Al, Hf, W, Ti—Zr—Be, Cu—Zr, Zr—Be, Ti—Cu, Zr—Cu—Ni—Al, Ti—Zr—Cu—Be and combinations thereof. In the instant context, the term ‘based on’ can be understood to mean that the specified element(s) are present in the greatest amount relative to any other present elements. Additionally, within the context of the instant application, the term “MG-based composition” can be understood reference an element, or aggregation of elements, that are capable of forming a metallic glass-based material (e.g. via being exposed to a sufficiently rapid, but viable, cooling rate). While several examples of suitable metallic glass-based materials are listed above, it should be reiterated that any suitable metallic glass-based composition can be incorporated in accordance with embodiments of the invention; for example, any of the metallic glass-based compositions listed in the disclosures cited and incorporated by reference above can be implemented. In many instances, the particular MG-based composition to be cast is based on an assessment of the anticipated operating environment for the insert. Thus, for example, in many instances the implemented MG-based composition is based the desire to match the coefficient of expansion with that of the component material that it is going to be affixed to. Accordingly, in many embodiments, titanium-based MG-based materials are implemented for use in conjunction with carbon composite materials. In particular, both titanium-based MG-based materials and carbon composite materials are generally characterized by relatively low coefficients of thermal expansion. In this way, when the insert is affixed to the carbon composite, the stresses between the insert and the carbon composite (e.g. in the epoxy bonding) can be reduced. Note also that both titanium-based MG-based materials and carbon composites are relatively light weight materials, and can thereby be well-suited for space applications. In particular, titanium-based MG-based inserts can offer high hardness at a relatively low density.

In many instances, the selection of the MG-based material to be implemented is based on the desire for one of: environmental resilience, toughness, wear resistance, hardness, density, machinability, and combinations thereof. For reference, Tables 1-6 list materials data that can be relied on in selecting a metallic glass-based composition to be implemented.

TABLE 1 Material Properties of MG-Based Materials relative to Heritage Engineering Materials Density Stiffness, E Tensile Tensile Elastic Limit Specific Hardness Material (g/cc) (GPa) Yield (MPa) UTS (MPa) (%) Strength (HRC) SS 15500 H1024 7.8 200 1140 1170 <1 146 36 Ti—6Al—4V STA 4.4 114 965 1035 <1 219 41 Ti—6Al—6V—4Sn STA 4.5 112 1035 1100 <1 230 42 Nitronic 60 CW 7.6 179 1241 1379 <1 163 40 Vascomax C300 8.0 190 1897 1966 <1 237 50 Zr-BMG 6.1 97 1737 1737 >1.8 285 60 Ti-BMGMC 5.2 94 1362 1429 >1.4 262 51 Zr-BMGMC 5.8 75 1096 1210 >1.4 189 48

TABLE 2 Material Properties of Select MG-Based Materials as a function of Composition BMG bcc ρ σ_(y) σ_(max) ε_(y) E T_(s) name atomic % weight % (%) (%) (g/cm³) (MPa) (MPa) (%) (GPa) (K) DV2 Ti₄₄Zr₂₀V₁₂Cu₅Be₁₉ Ti_(41.9)Zr_(36.3)V_(12.1)Cu_(6.3)Be_(1.4) 70 33 5.13 1597 1614 2.1 94.5 956 DV1 Ti₄₈Zr₂₀V₁₂Cu₅Be₁₅ Ti_(44.3)Zr_(35.2)V_(11.8)Cu_(6.7)Be_(2.6) 53 47 5.15 1362 1429 2.3 94.2 955 DV3 Ti₅₆Zr₁₈V₁₀Cu₄Be₁₂ Ti_(51.6)Zr_(31.6)V_(9.8)Cu_(4.9)Be_(2.1) 46 54 5.08 1308 1309 2.2 84.0 951 DV4 Ti₆₂Zr₁₅V₁₀Cu₄Be₉ Ti_(57.3)Zr_(26.4)V_(9.8)Cu_(4.9)Be_(1.6) 40 60 5.03 1086 1089 2.1 83.7 940 DVAI1 Ti₆₀Zr₁₆V₉Cu₅Al₃Be₉ Ti_(55.8)Zr_(28.4)V_(8.9)Cu_(3.7)Al_(1.6)Be_(1.6) 31 69 4.97 1166 1189 2.0 84.2 901 DVAI2 Ti₆₇Zr₁₁V₁₀Cu₅Al₂Be₅ Ti_(62.4)Zr_(19.5)V_(9.5)Cu_(6.2)Al₁Be_(0.9) 20 80 4.97 990 1000 2.0 78.7 998 Ti-6-4a Ti_(86.1)Al_(10.3)V_(3.6) Ti₉₀Al₆V₄ (Grade 5 Annealed) na na 4.43 754 882 1.0 113.8 1877 Ti-6-4s Ti_(86.1)Al_(10.3)V_(3.6)[Ref] Ti₉₉Al₆V₄ (Grade 5 STA) na na 4.43 1100 1170 ~1 114.0 1877 CP-Ti Ti₁₀₀ Ti₁₀₀ (Grade 2) na na 4.51 380 409 0.7 105.0 ~1930

TABLE 3 Material Properties of Select MG-Based Materials as a function of Composition σ_(max) ε_(tot) σ_(z) ε_(y) E ρ G CIT RoA Alloy (MPa) (%) (MPa) (%) (GPa) (g/cm³) (GPa) (J) (%) ν Zr_(38.6)Ti_(31.4)Nb₇Cu_(6.9)Be_(19.1) (DH1) 1512 9.58 1474 1.98 84.3 5.6 30.7 26 44 0.371 Zr_(38.3)Ti_(32.9)Nb_(7.3)Cu_(6.2)Be_(15.3) (DH2) 1411 10.8 1367 1.92 79.2 5.7 28.8 40 50 0.373 Zr_(39.6)Ti_(33.9)Nb_(7.6)Cu_(6.4)Be_(12.5) (DH3) 1210 13.10 1096 1.62 75.3 5.8 27.3 45 46 0.376 Zr_(41.2)Ti_(13.8)Cu_(12.5)Ni₁₀Be_(22.5) (Vitreloy 1) 1737 1.98 — — 97.2 6.1 35.9 8 0 0.355 Zr_(56.2)Ti_(13.8)Nb_(5.0)Cu_(6.9)Ni_(5.6)Be_(12.5) (LM 2) 1302 5.49 1046 1.48 78.8 6.2 28.6 24 22 0.375

TABLE 4 Material Properties as a Function of Composition and Structure, where A is Amorphous, X, is Crystalline, and C is Composite A/X/C 2.0Hv E (GPa) (CuZr42Al7Be10)Nb3 A 626.5 108.5 (CuZr46Al5Y2)Nb3 A 407.4 76.9 (CuZrAl7Be5)Nb3 A 544.4 97.8 (CuZrAl7Be7)Nb3 A 523.9 102.0 Cu40Zr40Al10Be10 A 604.3 114.2 Cu41Zr40Al7Be7Co5 C 589.9 103.5 Cu42Zr41Al7Be7Co3 A 532.4 101.3 Cu47.5Zr48Al4Co0.5 X 381.9 79.6 Cu47Zr46Al5Y2 A 409.8 75.3 Cu50Zr50 X 325.9 81.3 CuZr41Al7Be7Cr3 A 575.1 106.5 CuZrAl5Be5Y2 A 511.1 88.5 CuZrAl5Ni3Be4 A 504.3 95.5 CuZrAl7 X 510.5 101.4 CuZrAl7Ag7 C 496.1 90.6 CuZrAl7Ni5 X 570.0 99.2 Ni40Zr28.5Ti16.5Be15 C 715.2 128.4 Ni40Zr28.5Ti16.5Cu5Al10 X 627.2 99.3 Ni40Zr28.5Ti16.5Cu5Be10 C 668.2 112.0 Ni56Zr17Ti13Si2Sn3Be9 X 562.5 141.1 Ni57Zr18Ti14Si2Sn3Be6 X 637.3 139.4 Ti33.18Zr30.51Ni5.33Be22.88Cu8.1 A 486.1 96.9 Ti40Zr25Be30Cr5 A 465.4 97.5 Ti40Zr25Ni8Cu9Be18 A 544.4 101.1 Ti45Zr16Ni9Cu10Be20 A 523.1 104.2 Vit 1 A 530.4 95.2 Vit105 (Zr52.5Ti5Cu17.9Ni14.6Al10) A 474.4 88.5 Vit 106 A 439.7 88.3 Zr55Cu30Al10NiS A 520.8 87.2 Zr65Cu17.5Al7.5Ni10 A 463.3 116.9 DH1 C 391.1 84.7 GHDT (Ti30Zr35Cu8.2Be26.8) A 461.8 90.5

TABLE 5 Fatigue Characteristics as a Function of Composition Fracture Fatigue Strength Geometry Loading Frequency R- limit Fatigue Material (MPa) (mm) mode (Hz) ratio (MPa) ratio Zr_(56.2)Cu_(6.9)Ni_(5.6)Ti_(13.8)Nb_(5.0)Be_(12.5) 1480 3 × 3 × 30 4PB 25 0.1 ~296 0.200 Composites Zr_(41.2)Cu_(12.5)Ni₁₀Ti_(13.8)Nb_(5.0)Be_(22.5) 1900 3 × 3 × 50 4PB 25 0.1 ~152 0.080 Zr_(41.2)Cu_(12.5)Ni₁₀Ti_(13.8)Nb_(5.0)Be_(22.5) 1900 2 × 2 × 60 3PB 10 0.1 768 0.404 Zr_(41.2)Cu_(12.5)Ni₁₀Ti_(13.8)Nb_(5.0)Be_(22.5) 1900 2 × 2 × 60 3PB 10 0.1 359 0.189 Zr₄₄Ti₁₁Ni₁₀Cu₁₀Be₂₅ 1900 2.3 × 2.0 × 85 4PB 5-20 0.3 550 0.289 Zr₄₄Ti₁₁Ni₁₀Cu₁₀Be₂₅ 1900 2.3 × 2.0 × 85 4PB 5-20 0.3 390 0.205 Zr_(52.5)Cu_(17.9)Al₁₀Ni_(14.6)Ti₅ 1700 3.5 × 3.5 × 30 4PB 10 0.1 850 0.500 (Zr₅₈Ni_(13.6)Cu₁₈Al_(10.4))₉₉Nb₁ 1700 2 × 2 × 25 4PB 10 0.1 559 0.329 Zr₅₅Cu₃₀Ni₅Al₁₀ 1560 2 × 20 × 50 Plate 40 0.1 410 0.263 bend

TABLE 6 Fatigue Characteristics as a Function of Composition Fracture Fatigue Strength Geometry Loading Frequency R- limit Fatigue Material (MPa) (mm) mode (Hz) ratio (MPa) ratio Zr_(56.2)Cu_(6.9)Ni_(5.6)Ti_(13.8)Nb_(5.0)Be_(12.5) 1480 Ø2.98 TT 10 0.1 239 0.161 Composites Zr₅₅Cu₃₀Ni₅Al₁₀ Nano 1700 2 × 4 × 70 TT 10 0.1 ~340 0.200 Zr_(41.2)Cu_(12.5)Ni₁₀Ti_(13.8)Nb_(5.0)Be_(22.5) 1850 Ø2.98 TT 10 0.1 703 0.380 Zr_(41.2)Cu_(12.5)Ni₁₀Ti_(13.8)Nb_(5.0)Be_(22.5) 1850 Ø2.98 TT 10 0.1 615 0.332 Zr_(41.2)Cu_(12.5)Ni₁₀Ti_(13.8)Nb_(5.0)Be_(22.5) 1850 Ø2.98 TT 10 0.1 567 0.306 Zr_(41.2)Cu_(12.5)Ni₁₀Ti_(13.8)Nb_(5.0)Be_(22.5) 1900 — CC 5 0.1 ~1050 0.553 Zr_(41.2)Cu_(12.5)Ni₁₀Ti_(13.8)Nb_(5.0)Be_(22.5) 1900 — TC 5 −1 ~150 0.079 Zr₅₀Cu₄₀Al₁₀ 1821 Ø2.98 TT 10 0.1 752 0.413 Zr₅₀Cu₃₀Al₁₀Ni₁₀ 1900 Ø2.98 TT 10 0.1 865 0.455 Zr₅₀Cu₃₇Al₁₀Pd₃ 1899 Ø2.98 TT 10 0.1 983 0.518 Zr₅₀Cu₃₇Al₁₀Pd₃ 1899 Ø5.33 TT 10 0.1 ~900 0.474 Zr_(52.5)Cu_(17.9)Al₁₀Ni_(14.6)Ti₅ 1660 6 × 3 × 1.5 TT 1 0.1 — — Zr_(52.5)Cu_(17.9)Al₁₀Ni_(14.6)Ti₅ 1700 Ø2.98 TT 10 0.1 907 0.534 Zr₅₉Cu₂₀Al₁₀Ni₉Ti₃ 1580 6 × 3 × 1.5 TT 1 0.1 — — Zr₆₅Cu₁₅Al₁₀Ni₁₀ 1300 3 × 4 × 16 TT 20 0.1 ~280 0.215 Zr₅₅Cu₃₀Al₁₀Ni₅ 1560 1 × 2 × 5 TT 0.13 0.5 — —

Again, while several examples of MG-based materials that can be suitable for implementation within the instant context, embodiments of the invention are not limited to the materials listed in the tables. Rather, any suitable MG-based material can be implemented in accordance with embodiments of the invention.

Importantly, the MG-based composition can be cast into any suitable shape that can facilitate the structural interrelationship between two components. For example, FIGS. 4A-4I depict various geometries that can also be implemented in accordance with embodiments of the invention. Note that FIGS. 4A-4E illustrate threaded insert geometries that are characterized by a rough-textured outer surface, which can facilitate the bonding of the insert to a component. Of course, it should be appreciated that while certain rough textured surfaces are depicted, any of a variety of rough-textured surfaces can be incorporated in accordance with embodiments of the invention. FIG. 4F illustrates an eye-hook geometry can be used to facilitate a tethering structural relationship. In many instances, the formed insert is a threaded insert that includes extensions that flare out when engaged by a screw; extensions can serve to better ‘grip’ an associated component. FIGS. 5A-5C illustrate a threaded insert that includes extensions that deploy when the insert engages a screw in accordance with an embodiment of the invention. In particular, FIG. 5A illustrates a screw and an insert made from a MG-based material in accordance with an embodiment of the invention. FIG. 5B illustrates the screw being inserted into the threaded insert, and the extensions beginning to deploy. FIG. 5C illustrates that the screw is fully engaged with the threaded insert, and the extensions are fully deployed. This type of design can help the insert better adhere to a component that it is affixed to. To be clear, while several designs have been discussed and illustrated, any suitable insert design can be implemented in accordance with embodiments of the invention. For example, in some embodiments, cup and cone-shaped inserts are fabricated. Cup and cone-shaped inserts can be affixed to first and second components respectively, and can be used to align the first and second component materials. To reiterate, any suitable insert shape can be implemented in accordance with embodiments of the invention.

Returning back to FIG. 2, the method 200 further includes affixing 220 the insert to a first component that is to be structurally interrelated to a second component. The insert can be affixed 220 in any suitable way in accordance with embodiments of the invention. For example, in many embodiments, the insert is epoxy bonded to the component. In a number of embodiments, the operation of a mechanical lock (e.g. the extensions depicted in FIGS. 5A-5C) is relied in affixing the insert to the component. Any suitable technique can be used to affix the insert to the component. In some embodiments, the elastic nature of the constituent MG-based material is relied on to allow the insert to better adhere to a respective component. For example, in some embodiments, a threaded insert is affixed to a component via a press fit; subsequently, when a screw engages the threaded insert, it expands laterally, and thereby better adheres to the component. Note that MG-based materials can have elastic limits as high as 2% or more; accordingly they can accommodate a relatively substantial amount of elastic deformation, which in turn can be used to better affix the insert to the component. FIGS. 6A-6B illustrate a threaded insert fabricated from a MG-based material that expands upon engagement with a screw and thereby better adheres to its respective associated component in accordance with an embodiment of the invention. In particular, FIG. 6A depicts the insert press-bonded to an associated component; the depicted gap is meant to indicate that the insert is not as tightly bonded to the component as it could be. FIG. 6B illustrates that as the screw begins to engage the insert, it expands laterally and thereby more strongly adheres to the associated component. While several examples of affixing an insert to a component are discussed, it should be clear that any suitable way of affixing the insert to a first component can be implemented in accordance with embodiments of the invention.

Note that the component that the insert is affixed to can be any suitable component in accordance with embodiments of the invention. In many embodiments, the component is in the form of a sheet (e.g. sheet metal). In numerous embodiments, the component made from a relatively modern material, such as a carbon composite material. To be clear though, the component can take any of a variety of forms in accordance with embodiments of the invention.

Returning back to FIG. 2, the method 200 further includes structurally interrelating 230 a second component to the first component using the insert. In many embodiments, the insert is a threaded insert, a screw is used to fasten the second component to the first component using the threaded insert, and the first and second components are thereby structurally interrelated. In a number of embodiments, the insert is a cup-shaped insert designed to accommodate a cone-shaped geometry, the second component has an included cone-shaped geometry, the cup-shaped insert is used to align the first and second components, and the first and second components are thereby structurally interrelated. While several examples are given, it should be clear that the first and second components can be structurally interrelated in any suitable way in accordance with embodiments of the invention.

FIGS. 7A-7D schematically illustrates one example of a process in accordance with the method outlined in FIG. 2. In particular, FIG. 7A illustrates a first component to be structurally interrelated to a second component; in the illustrated embodiment, the first component is in the form of a sheet. As alluded to above, the component can be any suitable material in accordance with embodiments of the invention. FIG. 7B illustrates the formation of a threaded insert from a MG-based material. The insert can be formed using any suitable technique in accordance with embodiments of the invention, including any of the above-listed techniques. FIG. 7C illustrates embedding the insert within the first component. In particular, it is depicted that the insert is embedded within the first component using epoxy bonding. Of course, while epoxy bonding is depicted, the insert could have been affixed to the first component using any suitable technique in accordance with embodiments of the invention. FIG. 7D illustrates fastening a second component to the first component using a screw. As can be appreciated from the above discussion, the second component can take any of a variety of forms in accordance with embodiments of the invention. For example, it can conform to any of a variety of suitable geometries, and it can be made from any of a variety of suitable materials. While a certain process has been schematically illustrated in FIGS. 7A-7D, it should be clear that the process described with respect to FIG. 3 can be implemented in any of a variety of ways in accordance with embodiments of the invention.

FIGS. 8A-8B illustrate views of a MG-based insert relative to a conventional, steel-based insert. In particular, the MG-based insert appears on the right side of FIGS. 8A and 8B. Note that the two inserts are virtually identical in geometry, which demonstrates the viability of fabricating inserts from MG-based materials.

In general, as can be inferred from the above discussion, the above-mentioned concepts can be implemented in a variety of arrangements in accordance with embodiments of the invention. For example, while the process listed in FIG. 3 recites forming an insert using either a thermoplastic forming technique or a casting technique, in many embodiments, the insert is formed without using one of those techniques. Any suitable manufacturing technique can be used to form an insert from a metallic glass-based material in accordance with embodiments of the invention. Accordingly, although the present invention has been described in certain specific aspects, many additional modifications and variations would be apparent to those skilled in the art. It is therefore to be understood that the present invention may be practiced otherwise than specifically described. Thus, embodiments of the present invention should be considered in all respects as illustrative and not restrictive. 

1 An insert configured to structurally interrelate two components comprising: an elastically deformable body comprising a metallic glass-based material having an elastic limit of at least 1.4%, the body having an outer surface and defining an inner cavity; at least one opening disposed in the outer surface and communicating with the inner cavity; wherein the outer surface of the body is adapted to engage a first component; and wherein the inner cavity is adapted to engage a second component such that during such engagement at least the outer surface of the body elastically deforms and laterally expands to securely engage the first component.
 2. The insert of claim 1, wherein the inner cavity is threaded.
 3. The insert of claim 1, wherein the inner cavity comprises an eye-hook structure.
 4. The insert of claim 1, wherein the outer surface is textured.
 5. The insert of claim 1, wherein the outer surface further comprises extensions configured to deploy within the first component as the insert is engaged by the second component.
 6. (canceled)
 7. The insert of claim 1, wherein the inner cavity is one of either a cup-shaped geometry or a cone-shaped geometry.
 8. The insert of claim 1, wherein the metallic glass-based composition is based on one of: Ti, Zr, Cu, Ni, Fe, Pd, Pt, Ag, Au, Al, Hf, W, Ti—Zr—Be, Cu—Zr, Zr—Be, Ti—Cu, Zr—Cu—Ni—Al, Ti—Zr—Cu—Be, and combinations thereof.
 9. The insert of claim 8, wherein the metallic glass-based composition is based on titanium.
 10. The insert of claim 1, wherein the outer surface further comprises a layer of epoxy.
 11. The insert of claim 1, wherein the inner cavity is threaded and the second component comprises a threaded screw.
 12. The insert of claim 1, wherein the outer surface is threaded.
 13. An insert configured to structurally interrelate two components comprising: a body comprising a metallic glass-based material having an elastic limit of at least 1.4%, the body having an outer surface and defining an inner cavity; at least one opening disposed in the outer surface and communicating with the inner cavity; wherein the outer surface of the body is adapted to engage a first component as a press fitting; and wherein the inner cavity is threaded and adapted to engage a threaded second component such that during such engagement at least the outer surface of the body elastically deforms and laterally expands to securely engage the first component.
 14. The method of claim 13, wherein the outer surface is textured.
 15. The insert of claim 13, wherein the outer surface further comprises extensions configured to deploy within the first component as the insert is engaged by the second component.
 16. The insert of claim 13, wherein the inner cavity is one of either a cup-shaped geometry or a cone-shaped geometry.
 17. An insert of claim 13, wherein the metallic glass-based composition is based on one of: Ti, Zr, Cu, Ni, Fe, Pd, Pt, Ag, Au, Al, Hf, W, Ti—Zr—Be, Cu—Zr, Zr—Be, Ti—Cu, Zr—Cu—Ni—Al, Ti—Zr—Cu—Be, and combinations thereof.
 18. The insert of claim 17, wherein the metallic glass-based composition is based on titanium.
 19. The insert of claim 13, wherein the outer surface further comprises a layer of epoxy.
 20. (canceled) 